Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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OXIMETER RED AND IR ZERO CALIBRATION CONTROL
BACKGROUND OF THE INVENTION
[0001] The present invention relates to oximeters, and in particular to LED
drive circuits in
pulse oximeters.
[0002] Pulse oximetry is typically used to measure various blood chemistry
characteristics
including, but not limited to, the blood-oxygen saturation of hemoglobin in
arterial blood, the
volume of individual blood pulsations supplying the tissue, and the rate of
blood pulsations
corresponding to each heartbeat of a patient. Measurement of these
characteristics has been
accomplished by use of a non-invasive sensor which scatters light through a
portion of the
patient's tissue where blood perfuses the tissue, and photoelectrically senses
the absorption of
light in such tissue. The amount of light absorbed at various wavelengths is
then used to
calculate the amount of blood constituent being measured.
[0003] The light scattered through the tissue is selected to be of one or more
wavelengths
that are absorbed by the blood in an amount representative of the amount of
the blood
constituent present in the blood. The amount of transmitted light scattered
through the tissue
will vary in accordance with the changing amount of blood constituent in the
tissue and the
related light absorption. For measuring blood oxygen level, such sensors have
typically been
provided with a light source that is adapted to generate light of at least two
different
wavelengths, and with photodetectors sensitive to both of those wavelengths,
in accordance
with known techniques for measuring blood oxygen saturation.
[0004] Known non-invasive sensors include devices that are secured to a
portion of the
body, such as a finger, an ear or the scalp. In animals and humans, the tissue
of these body
portions is perfused with blood and the tissue surface is readily accessible
to the sensor.
[0005] The light sources, typically light emitting diodes (LEDs), need to be
driven with
current to activate them. In order to reduce the effects of leakage and
capacitively coupled
transients, it is desirable to be able to drive one of the LEDs, without any
current going
through the other one. Typically, this can be done by controlling the duty
cycle with the
processor in the pulse oximeter. However, using the duty cycle controls to
eliminate current
through one of the LEDs has been discovered to still involve an amount of
leakage and
capacitively coupled transients that is undesirable.
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BRIEF SUMMARY OF THE INVENTION
[0006] The present invention provides a pulse oximeter with drive lines for
driving red and
IR LEDs, and a drive circuit for driving those drive lines. A processor
controls the drive
circuit using a red zero output line and an IR zero output line directly
connected between the
processor and the drive circuit. This allows a control signal to directly
control the turning off
of either the red or IR drive transistors which direct forward current flow
through the red and
IR LEDs.
[0007] In one embodiment, the red and IR zero output lines are connected to a
programmed
logic circuit. The programmed logic circuit, which is controlled by the
processor, provides
the various timing signals for the transistors of the drive circuit. In one
embodiment, the
drive circuit includes an H-bridge circuit with red and IR FET drive
transistors.
[0008] For a further understanding of the nature and advantages of the present
invention,
reference should be made to the following description taken in conjunction
with the
accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] Fig. 1 is a block diagram of an oximeter incorporating the present
invention.
[0010] Fig. 2 is a circuit diagram of a LED drive circuit according to an
embodiment of the
present invention.
[0011] Fig. 3 is a block diagram of one embodiment of the logic for generating
the timing
and control signals for the circuit of Fig. 2.
DETAILED DESCRIPTION OF THE INVENTION
Oximeter Front End
[0012] Fig. 1 illustrates an embodiment of an oximetry system incorporating
the present
invention. A sensor 10 includes red and infrared LEDs and a photodetector.
These are
connected by a cable 12 to a board 14. LED drive current is provided by an LED
drive
interface 16. The received photocurrent from the sensor is provided to an I-V
interface 18.
The IR and red voltages are then provided to a sigma-delta interface 20
incorporating the
present invention. The output of sigma-delta interface 20 is provided to a
microcontroller 22
which includes a 10-bit A1D converter. Controller 22 includes flash memory for
a program,
and EEPROM memory for data. The processor also includes a controller chip 24
connected
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to a flash memory 26. Finally, a clock 2.8 is used and an interface 30 to a
digital calibr~.tion
in the sensor 10 is provided. A separate host 32 receives the processed
information, as well
as receiving an analog signal on a line 34 for providing an analog display.
LED Drive Circuit
[0013] Fig. 2 is a circuit diagram of the LED drive circuit according to an
embodiment of
the invention, which forms a portion of LED drive interface 16 of Fig. 1. A
voltage
regulator 36 provides a voltage separate from the voltage supply for the
overall oximeter
circuitry. The output is provided as a 4.5 volt signal on line 38, with the
level being set by
the feedback resistor divider of resistors R89 and R90. The voltage on line 38
is provided to
a FET transistor Q11 to an inductor L6. The current through inductor L6 is
provided by a
switch 40 to one of capacitors C65 and C66, which store charge for the red and
IR LEDs,
respectively. A red/IR control signal on line 42 selects the switch position
under control of
the oximeter processor. A control signal LED PWM gate on line 44 controls the
switching of
transistor switch Ql 1.
[0014] Once the capacitors are charged up, the control signal on line 44 turns
off
switch Q11 and current is provided from either capacitor C65 or C66, through
switch 40 and
inductor L6 to either the red anode line 46 or the IR anode line 48 by way of
transistors QS
and Q6, respectively. A signal "red gate" turns on transistor Q5, while its
inverse, "/red gate"
turns off transistor Q7. This provides current through the red anode line 46
to the back to
back LEDs 50, with the current returning through the IR anode to transistor Q8
and through
resistor R10 to ground. Transistor Q8 is turned on by the signal "/IR gate"
while the inverse
of this signal, "IR gate" turns off transistor Q6. The signals are reversed
when the IR anode
is to be driven, with the "IR gate" and "red gate" signals, and their
inverses, changing state, so
that current is provided through transistor Q6 to IR anode 48 and returns
through red anode
46 and through transistor Q7 to resistor R10 and ground. The "LED current
sense" signal is
read for calibration purposes not relevant to the present invention.
[0015] When the current from the capacitor C65 or C66 is provided through
inductor L6 to
the LEDs, and that current is switched off at the desired time, transistor Q11
is turned on so
that the remaining current during the transition can be dumped into capacitor
C64. This
addresses the fact that the FET transistor switching is not instantaneous.
Subsequently, C64
will dump its current through Q11 and inductor L6 into the capacitors when
they are
recharged.
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[0016] Resistor R38 and capacitor C67 are connected in parallel to inductor L6
to protect
against signal spikes, and provide a smooth transition. Connected to inductor
L6 is a
sampling circuit with a switch 52 controlled by an LED sample hold signal on
line 54 to
sample the signals and provide them through an amplifier 56 to a "LED current"
signal on
line 58 which is read by the processor. An integrating capacitor C68 is
provided in parallel to
amplifier 56. A switch 60 responds to a "clear LED sample" signal to operate
the switch to
short out the capacitor between samples.
[0017] The sample and hold circuit measures the voltage at node T18, between
capacitor C69 and inductor L6, to determine the current. Capacitor C69 is
111000 of the
value of capacitors C65 and C66. Thus, a proportional current is provided
through C69,
which is injected through switch 52 to integrating capacitor C68 to provide a
voltage which
can be measured at the output of amplifier 56 on line 58. The voltage measured
by the
processor on line 58 is used as a feedback, with the processor varying the
width of the pulse
delivered to transistor Ql 1 to selectively vary the amount of energy that's
delivered to the
capacitors 65 and 66, and then is eventually discharged to the LEDs 50. A PI
(Proportional
Integral) loop inside the processor then controls the PWM signal at Q11. This
allows precise
control of the LED intensity, allowing it to be maximized, if desired, without
exceeding the
desired limits (to avoid burning the patient, etc.).
[0018] The lower left of the diagram shows a "4.5 v LED disable" signal which
is used by
the microprocessor to turn off the voltage regulator 36 in certain instances.
For example,
diagnostics looking for shorts in a new sensor plugged in will turn off the
voltage regulator if
there is a problem with the LED line.
Zero Calibration Control
(0019] Fig. 3 illustrates processor 22, from Fig. l, connected to programmed
logic 62,
which is in the LED drive interface 16 in Fig. 1. Programmed logic 62 provides
the different
control signals used by the circuit of Fig. 2 in response to basic timing
signals from the
processor of a clock, a sync pulse, and a pulse width signal.
[0020] As can be seen, processor 22 also provides a red zero signal on a line
64 and an IR
zero signal on a line 66. These two signals go to programmed logic circuit 62.
Programmed
logic 62, in response to assertion of the red zero signal, will provide
appropriate control
signals on the red gate, !red gate, IR gate and lIR gate control outputs to
control the drive
transistors in Figure 2. In particular, assertion of the red zero signal will
cause the red gate
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signal to turn off transistor QS and transistor Q8. The programmable logic for
switching
between the LEDs still functions, but is overridden by this zero signal. Thus,
the red gate is
held at its value regardless of efforts by the programmable logic state
machine to cycle it on
and off. Similarly, assertion of the IR zero signal on line 66 will cause
program logic
circuit 62 to turn off transistor Q6 with the IR gate signal, and turn off
transistor Q7 with the
/red gate signal.
[0021] These control signals thus assure that current only flows through the
red LED or the
IR LED, without any leakage due to switching between them while the
appropriate red zero
or IR zero signal is asserted. This significantly reduces any switching
leakage due to use of
the duty cycle controls and any capacitively coupled switching transients.
[0022] As will be understood by those of skill in the art, the present
invention can be
embodied in other specific forms without departing from the essential
characteristics thereof.
For example, a different drive transistor structure could be used, such as for
LEDs that are not
configured back-to-back, but rather have separate connections which are
separately driven.
Accordingly, the foregoing description is intended to be illustrative, but not
limiting, of the
scope of the invention which is set forth in the following claims.
